INTRODUCTION: Intestinal epithelial cells are rapidly renewed throughout life by intestinal stem cells (ISCs). ISC function is regulated by niche factors that orchestrate cellular proliferation and differentiation. Of these, Notch signaling is essential for ISC self-renewal and regulates the cell fate choice between absorptive cells (enterocyte) vs secretory (Paneth, goblet, enteroendocrine, and tuft) cells. Yet, the Notch niche is not fully defined. In the mature small intestine, Paneth cells neighbor each ISC and act as Notch niche cells, providing the Notch signal by expressing the Notch ligands DLL1 and DLL4 on their surface. However, studies in mice have shown that ISCs can function in the immature intestine before Paneth cells are formed, and when Paneth cells are depleted in the adult intestine. We previously observed that acute Notch inhibition via the inhibitor dibenzazepine (DBZ) resulted in Paneth cell apoptosis with intact ISCs displaying transient dysfunction. Here, we aimed to define the Notch niche after Paneth cell apoptosis in adult mice and in the developing intestine. We hypothesized that during acute Notch inhibition, ISCs remodel to compensate for Paneth cell loss by activating Notch ligand expression, and that this remodeling mimics the state of immature ISCs prior to Paneth cell emergence. METHODS: We isolated Lgr5+ ISCs by FACS from Lgr5-GFP-CreERT2 mice 24 hours after DBZ or vehicle treatment and performed bulk RNAseq analysis. To define the Notch niche during development, we analyzed postnatal intestines from Notch ligand reporter mice (Dll1-mCherry and Dll4-mCherry) crossed with the ISC reporter mice (Lgr5-GFP-CreERT2). RESULTS: ISCs isolated from Paneth cell-depleted intestines upregulated expression of Notch ligands Dll4 and Dll4 and various secretory cell markers, with expected downregulation of Notch target genes, but no alteration of other stem cell genes. This suggests that after acute Notch inhibition, Lgr5+ ISCs maintain partial stem cell identity while acquiring a signature resembling that of secretory progenitors. In the immature intestine, we showed by immunohistology that sporadic cells expressing secretory cell markers (LYZ, MUC2, and CHGA) localized to the intervillus region and co-stained with Dll1- or Dll4-mCherry+. This suggests that multiple differentiated cell types could provide the Notch signal to immature ISCs. We also observed occasional Lgr5-GFP+ ISCs that were co-positive for Dll1-mCherry, suggesting that immature ISCs can express Notch ligands at homeostasis. Further experimentation will determine whether these Dll1+ ISCs are similar to the remodeled adult ISCs after Paneth cell depletion. CONCLUSIONS: Acute Notch inhibition directly remodels ISCs to express the Notch ligands, Dll1 and Dll4 in the adult intestine. In the immature intestine, multiple secretory cell types appear to comprise the immature Notch niche. This project was funded by NIH R01 DK118023 awarded to Dr. Linda Samuelson. This is the full abstract presented at the American Physiology Summit 2024 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.
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